Method of manufacturing a lithium-ion secondary battery

ABSTRACT

A method of manufacturing a lithium-ion secondary battery of the present invention includes at least four steps as follows: an initial charging step of charging the lithium-ion secondary battery, which has not been subjected to initial charging, under a temperature environment ranging of equal to or higher than −20° C. and equal to or lower than 15° C.; an aging step of leaving the lithium-ion secondary battery under a temperature environment ranging of equal to or higher than 30° C. and equal to or lower than 80° C. after the initial charging step; a short circuit detecting step of detecting the presence or absence of a short circuit of the lithium-ion secondary battery by measuring a voltage drop quantity of the lithium-ion secondary battery and comparing the voltage drop quantity with a reference value; and a sorting step of sorting out a lithium-ion secondary battery in which no short circuit is detected.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a National Stage of International Application No.PCT/JP2016/067758 filed Jun. 15, 2016, claiming priority based onJapanese Patent Application No. 2015-132834 filed Jul. 1, 2015, thecontents of all of which are incorporated herein by reference in theirentirety.

TECHNICAL FIELD

The present invention relates to a method of manufacturing a lithium-ionsecondary battery and a method of evaluating a lithium-ion secondarybattery.

BACKGROUND ART

In a case where a conductive foreign substance such as metal isincorporated in a lithium-ion secondary battery, there is a possibilitythat a short circuit will occur between positive and negative electrodeswhen the lithium-ion secondary battery is in use, resulting in a voltagedrop or heat generation.

Therefore, in a step of manufacturing a lithium-ion secondary battery, abattery having a conductive foreign substance incorporated therein isdetected and the battery is appraised as a defective unit and is removedfrom a product.

For example, Patent Document 1 (Japanese Unexamined Patent PublicationNo. 2005-209528) discloses a technology of detecting a conductiveforeign substance incorporated in a lithium-ion secondary battery.

Patent Document 1 discloses a method of inspecting a secondary batteryincluding an initial charging step of performing initial charging of asecondary battery at a predetermined temperature by localizing metalimpurities on an electrode and causing the metal impurities to beprecipitated, and a micro-short detecting step of detecting amicro-short between a positive electrode and a negative electrode afterthe initial charging step.

RELATED DOCUMENT Patent Document

[Patent Document 1] Japanese Unexamined Patent Publication No.2005-209528

SUMMARY OF THE INVENTION Technical Problem

Upon investigation of the inventors, it has become clear that the methoddisclosed in Patent Document 1 has low sensitivity for detecting aconductive foreign, for example, it is not possible to detect alithium-ion secondary battery, within a practical period of time, inwhich a minute amount of stainless steel having a high risk of beingincorporated during a manufacturing step is incorporated.

The present invention has been made in consideration of the foregoingcircumstances and provides a method of manufacturing a lithium-ionsecondary battery capable of efficiently obtaining a highly reliablelithium-ion secondary battery in which a short circuit is unlikely tooccur between positive and negative electrodes, and a method ofevaluating a lithium-ion secondary battery capable of accuratelydetecting a lithium-ion secondary battery in which a short circuit islikely to occur between positive and negative electrodes.

Solution to Problem

According to the present invention, there is provided a method ofmanufacturing a lithium-ion secondary battery including an initialcharging step of charging the lithium-ion secondary battery, which hasnot been subjected to initial charging, under a temperature environmentranging of equal to or higher than −20° C. and equal to or lower than15° C.; an aging step of leaving the lithium-ion secondary battery undera temperature environment ranging of equal to or higher than 30° C. andequal to or lower than 80° C. after the initial charging step; a shortcircuit detecting step of detecting the presence or absence of a shortcircuit of the lithium-ion secondary battery by measuring a voltage dropquantity of the lithium-ion secondary battery and comparing the voltagedrop quantity with a reference value; and a sorting step of sorting outa lithium-ion secondary battery in which no short circuit is detected.

Moreover, according to the present invention, there is provided a methodof manufacturing a lithium-ion secondary battery including an initialcharging step of charging the lithium-ion secondary battery, which hasnot been subjected to initial charging, under a condition in whichviscosity of an electrolytic solution is equal to or higher than 6.0mPa·s; an aging step of leaving the lithium-ion secondary battery undera condition in which viscosity of an electrolytic solution is equal toor lower than 4.5 mPa·s after the initial charging step; a short circuitdetecting step of detecting the presence or absence of a short circuitof the lithium-ion secondary battery by measuring a voltage dropquantity of the lithium-ion secondary battery and comparing the voltagedrop quantity with a reference value; and a sorting step of sorting outa lithium-ion secondary battery in which no short circuit is detected.

Moreover, according to the present invention, there is provided a methodof evaluating a lithium-ion secondary battery including a charging stepof charging the lithium-ion secondary battery under a temperatureenvironment ranging of equal to or higher than −20° C. and equal to orlower than 15° C., an aging step of leaving the lithium-ion secondarybattery under a temperature environment ranging of equal to or higherthan 30° C. and equal to or lower than 80° C. after the charging step,and a short circuit detecting step of detecting the presence or absenceof a short circuit of the lithium-ion secondary battery by measuring avoltage drop quantity of the lithium-ion secondary battery and comparingthe voltage drop quantity with a reference value.

Moreover, according to the present invention, there is provided a methodof evaluating a lithium-ion secondary battery including a charging stepof charging the lithium-ion secondary battery under a condition in whichviscosity of an electrolytic solution is equal to or higher than 6.0mPa·s, an aging step of leaving the lithium-ion secondary battery undera condition in which viscosity of an electrolytic solution is equal toor lower than 4.5 mPa·s after the charging step, and a short circuitdetecting step of detecting the presence or absence of a short circuitof the lithium-ion secondary battery by measuring a voltage dropquantity of the lithium-ion secondary battery and comparing the voltagedrop quantity with a reference value.

Advantageous Effects of Invention

According to the present invention, it is possible to provide the methodof manufacturing a lithium-ion secondary battery capable of efficientlyobtaining a highly reliable lithium-ion secondary battery in which ashort circuit is unlikely to occur between positive and negativeelectrodes, and the method of evaluating a lithium-ion secondary batterycapable of accurately detecting a lithium-ion secondary battery in whicha short circuit is likely to occur between positive and negativeelectrodes.

BRIEF DESCRIPTION OF THE DRAWINGS

The objects, other objects, the features, and the advantages describedabove become clearer by preferable embodiments and the accompanyingdrawings described below.

FIG. 1 is a flow chart illustrating an example of a method ofmanufacturing a lithium-ion secondary battery according to a firstembodiment.

FIG. 2 is a flow chart illustrating an example of a method ofmanufacturing a lithium-ion secondary battery according to a secondembodiment.

FIG. 3 is a flow chart illustrating an example of a method of evaluatinga lithium-ion secondary battery according to a third embodiment.

FIG. 4 is a flow chart illustrating an example of a method of evaluatinga lithium-ion secondary battery according to a fourth embodiment.

DESCRIPTION OF EMBODIMENTS

Hereinafter, embodiments of the present invention will be describedusing the drawings. In all of the drawings, common reference signs willbe applied to similar constituent elements, and description will not berepeated. Unless otherwise noted, “to” between numbers in sentencesindicates a range of equal to or more than a number and equal to or lessthan the other number.

First Embodiment: Method of Manufacturing Lithium-Ion Secondary Battery

First, a method of manufacturing a lithium-ion secondary batteryaccording to a first embodiment will be described. FIG. 1 is a flowchart illustrating an example of the method of manufacturing alithium-ion secondary battery according to the first embodiment.

The method of manufacturing a lithium-ion secondary battery of thepresent embodiment includes at least four steps (A1) to (A4) as follows:

(A1) an initial charging step of charging the lithium-ion secondarybattery, which has not been subjected to initial charging, under atemperature environment ranging of equal to or higher than −20° C. andequal to or lower than 15° C.;

(A2) an aging step of leaving the lithium-ion secondary battery under atemperature environment ranging of equal to or higher than 30° C. andequal to or lower than 80° C. after the initial charging step (A1);

(A3) a short circuit detecting step of detecting the presence or absenceof a short circuit of the lithium-ion secondary battery by measuring avoltage drop quantity of the lithium-ion secondary battery and comparingthe voltage drop quantity with a reference value; and

(A4) a sorting step of sorting out a lithium-ion secondary battery inwhich no short circuit is detected.

According to the method of manufacturing a lithium-ion secondary batteryof the present embodiment, when at least the four steps (A1) to (A4)described above are included, a lithium-ion secondary battery having aconductive foreign substance incorporated therein can be detected withhigh sensitivity, so that it is possible to efficiently obtain alithium-ion secondary battery in which a short circuit is unlikely tooccur between positive and negative electrodes.

Upon investigation of the inventors, it has become clear that the methoddisclosed in Patent Document 1 has low sensitivity for detecting aconductive foreign, for example, it is not possible to detect alithium-ion secondary battery, within a practical period of time, inwhich a minute amount of stainless steel having a high risk of beingincorporated during a manufacturing step is incorporated.

Thus, the inventors have intensively and repetitively investigated inorder to achieve the objects described above. As a result, it has beenfound that sensitivity for detecting a conductive foreign substanceinside a lithium-ion secondary battery is improved by respectivelyperforming the initial charging step (A1) and the aging step (A2) withinparticular temperature ranges, and the present invention has beencompleted.

That is, in the method of manufacturing a lithium-ion secondary batteryof the present embodiment, as described above, the ambient temperaturesin the initial charging step (A1) and the aging step (A2) arerespectively adjusted to particular ranges. It is assumed that when theambient temperature in the initial charging step (A1) is within therange described above, seed crystal of a precipitate of a conductiveforeign substance can be formed in an acute-angled manner. In addition,it is assumed that when the ambient temperature in the aging step (A2)is within the range described above, the seed crystal can groweffectively while the acute-angled form is maintained.

For the reason described above, according to the method of manufacturinga lithium-ion secondary battery of the present embodiment, it ispossible to efficiently detect and eliminate a lithium-ion secondarybattery in which a conductive foreign substance, such as stainless steelthat is difficult to be detected by a detection technology in therelated art, having a high risk of being incorporated during amanufacturing step is incorporated. That is, according to the method ofmanufacturing a lithium-ion secondary battery of the present embodiment,it is possible to remove a lithium-ion secondary battery as a defectiveunit in which a short circuit occurs between the positive and negativeelectrodes due to a precipitate of a conductive foreign substance sothat deterioration of battery performance is likely to occur in a laterstage in a case where a force is applied such that the positiveelectrode and the negative electrode approach each other when in actualuse or in a case of being used for a long period of time even though nodefect has occurred at the time of inspection. Therefore, it is possibleto efficiently obtain a highly reliable lithium-ion secondary battery inwhich a short circuit is unlikely to occur between the positive andnegative electrodes.

Hereinafter, each of the steps will be described.

(Initial Charging Process (A1))

First, a lithium-ion secondary battery which has not been subjected toinitial charging is charged under a temperature environment ranging ofequal to or higher than −20° C. and equal to or lower than 15° C.

The initial charging step (A1) is a step in which a lithium-ionsecondary battery in a state where assembling is completed (anelectrolytic solution is injected, and the battery is sealed) is chargedfor the first time to a predetermined capacity. It is preferable thatcharging in the initial charging step (A1) is carried out by constantcurrent/constant voltage charging (CCCV charging).

The ambient temperature in the initial charging step (A1) ranges ofequal to or higher than −20° C. and equal to or lower than 15° C.However, the ambient temperature preferably ranges of equal to or higherthan −10° C. and equal to or lower than 10° C. and more preferablyranges of equal to or higher than −8° C. and equal to or lower than 8°C. When the temperature in the initial charging step (A1) is equal to orlower than the upper limit value, it is assumed that seed crystal of aprecipitate of a conductive foreign substance can be formed in anacuter-angled manner. In addition, when the temperature in the initialcharging step (A1) is equal to or higher than the lower limit value,deterioration of the cell characteristics (particularly, charging anddischarging capacity) of a lithium-ion secondary battery in the initialcharging step (A1) can be further suppressed.

In addition, from the viewpoint of being able to improve sensitivity fordetecting a conductive foreign substance, the viscosity of anelectrolytic solution in the lithium-ion secondary battery in theinitial charging step (A1) is preferably equal to or higher than 6.0mPa·s and is more preferably equal to or higher than 7.0 mPa·s. In thefirst to fourth embodiments, as the viscosity of an electrolyticsolution, viscosity measured by using a tuning fork viscometer(manufactured by SEKONIC CORPORATION, brand name: Visco Mate VM-100) isindicated.

It is assumed that when the viscosity of an electrolytic solution isequal to or higher than the lower limit value, diffusion of ion of aconductive foreign substance in the electrolytic solution is suppressed,and seed crystal of a precipitate of a conductive foreign substance canbe formed in an acuter-angled manner, so that sensitivity for detectinga conductive foreign substance can be improved.

For example, the upper limit value for the viscosity of an electrolyticsolution in the lithium-ion secondary battery in the initial chargingstep (A1) is equal to or lower than 15 mPa·s.

Here, the viscosity of an electrolytic solution in the lithium-ionsecondary battery can be adjusted by adjusting the ambient temperaturein the initial charging step (A1) or adjusting the type or concentrationof an electrolyte, the type of a menstruum in which the electrolyte isdissolved, and the like.

(Aging Process (A2))

Subsequently, the lithium-ion secondary battery is left under atemperature environment ranging of equal to or higher than 30° C. andequal to or lower than 80° C. after the initial charging step (A1).

The ambient temperature in the aging step (A2) ranges of equal to orhigher than 30° C. and equal to or lower than 80° C. However, theambient temperature preferably ranges of equal to or higher than 35° C.and equal to or lower than 70° C. and more preferably ranges of equal toor higher than 40° C. and equal to or lower than 65° C. When thetemperature in the aging step (A2) is equal to or lower than the upperlimit value, deterioration of the cell characteristics (particularly,charging and discharging capacity) of a lithium-ion secondary battery inthe aging step (A2) can be further suppressed. In addition, when thetemperature in the aging step (A2) is equal to or higher than the lowerlimit value, the seed crystal of the conductive foreign substance cangrow faster. Therefore, a conductive foreign substance inside alithium-ion secondary battery can be detected within a shorter period oftime.

In addition, when the ambient temperature in the initial charging step(A1) is set to T₁ [° C.] and the ambient temperature in the aging step(A2) is set to T₂ [° C.], (T₂−T₁) is preferably equal to or higher than30° C. and is more preferably equal to or higher than 40° C.

In this manner, a conductive foreign substance can be detected withhigher sensitivity within a shorter period of time.

In addition, it is preferable that the aging step (A2) is performedwithout carrying out charging and discharging even once after theinitial charging step (A1). In this manner, a conductive foreignsubstance can be detected within a shorter period of time.

In addition, the voltage of a lithium-ion secondary battery when theaging step (A2) starts is preferably equal to or higher than 3.80 V, ismore preferably equal to or higher than 3.90 V, and is particularlypreferably equal to or higher than 4.00 V. When the voltage of alithium-ion secondary battery when the aging step (A2) starts is equalto or higher than the lower limit value, a conductive foreign substancecan be detected with higher sensitivity within a shorter period of time.

In addition, the voltage of a lithium-ion secondary battery when theaging step (A2) starts is preferably equal to or lower than 4.40 V, ismore preferably equal to or lower than 4.30 V, and is particularlypreferably equal to or lower than 4.20 V. When the voltage of alithium-ion secondary battery when the aging step (A2) starts is equalto or lower than the upper limit value, it is possible to furthersuppress deterioration of the cell characteristics (particularly,charging and discharging capacity) of a lithium-ion secondary battery inthe aging step (A2).

In addition, in the aging step (A2), the lithium-ion secondary batteryis preferably left for equal to or longer than two days, is morepreferably left for equal to or longer than four days, and isparticularly preferably left for equal to or longer than five days. Inthe aging step (A2), when the lithium-ion secondary battery is left forequal to or higher than the lower limit value, a conductive foreignsubstance can be detected with higher sensitivity.

In addition, in the aging step (A2), the lithium-ion secondary batteryis preferably left for equal to or shorter than ten days leave and ismore preferably left for equal to or shorter than eight days. Accordingto the method of manufacturing a lithium-ion secondary battery of thepresent embodiment, a conductive foreign substance inside a lithium-ionsecondary battery can be sensitively detected. Therefore, even thoughthe period of time for being left in the aging step (A2) is equal to orlower than the upper limit value, a lithium-ion secondary battery havinga conductive foreign substance incorporated therein can be accuratelydetected and eliminated, so that it is possible to efficiently obtain alithium-ion secondary battery in which a short circuit is unlikely tooccur between positive and negative electrodes.

In addition, from the viewpoint of being able to detect a conductiveforeign substance inside a lithium-ion secondary battery within ashorter period of time, the viscosity of an electrolytic solution in thelithium-ion secondary battery in the aging step (A2) is preferably equalto or lower than 4.5 mPa·s, is more preferably equal to or lower than4.0 mPa·s, and is particularly preferably equal to or lower than 3.5mPa·s.

It is assumed that when the viscosity of an electrolytic solution isequal to or lower than the upper limit value, diffusion of ion of aconductive foreign substance in the electrolytic solution becomesfavorable, and the seed crystal of a conductive foreign substance cangrow faster. Therefore, a conductive foreign substance inside alithium-ion secondary battery can be detected within a shorter period oftime.

For example, the lower limit value for the viscosity of an electrolyticsolution in the lithium-ion secondary battery in the aging step (A2) isequal to or higher than 1.5 mPa·s.

Here, the viscosity of an electrolytic solution can be adjusted byadjusting the ambient temperature in the aging step (A2) or adjustingthe type or concentration of an electrolyte, the type of a menstruum inwhich the electrolyte is dissolved, and the like.

(Short Circuit Detecting Process (A3))

Subsequently, the presence or absence of a short circuit of thelithium-ion secondary battery is detected by measuring a voltage dropquantity of the lithium-ion secondary battery and comparing the voltagedrop quantity with a reference value. A lithium-ion secondary batteryhaving no short circuit is appraised as a quality product.

The short circuit detecting step (A3) may be performed simultaneouslywith the aging step (A2) or may be performed after the aging step (A2).

For example, the short circuit detecting step (A3) is performed throughself-discharging. A lithium-ion secondary battery is self-discharged bybeing left at a specified temperature for a predetermined period oftime. For example, the specified temperature ranges of equal to orhigher than 15° C. and equal to or lower than 40° C. The predeterminedperiod of time preferably ranges of equal to or longer than 1 day andequal to or shorter than 20 days, more preferably ranges of equal to orlonger than 2 days and equal to or shorter than 14 days, andparticularly preferably ranges of equal to or longer than 3 days andequal to or shorter than 7 days. When the lithium-ion secondary batteryis left for equal to or longer than the lower limit value, the voltagedrop quantity further increases, so that a conductive foreign substancecan be detected with higher accuracy.

In addition, According to the method of manufacturing a lithium-ionsecondary battery of the present embodiment, a conductive foreignsubstance inside a lithium-ion secondary battery can be sensitivelydetected. Therefore, even though the period of time for being left inthe short circuit detecting step (A3) is equal to or lower than theupper limit value, a lithium-ion secondary battery having a conductiveforeign substance incorporated therein can be accurately detected andeliminated, so that it is possible to efficiently obtain a lithium-ionsecondary battery in which a short circuit is unlikely to occur betweenpositive and negative electrodes.

Most lithium-ion secondary batteries undergo self-discharging whichoccurs ordinarily due to a reason other than a conductive foreignsubstance. Therefore, a lithium-ion secondary battery in which abnormalself-discharging greater than self-discharging occurring ordinarily hasoccurred is determined as a foreign substance-incorporated battery.

For example, the voltage drop quantity can be obtained based on thedifference between the voltage before the self-discharging and thevoltage after the self-discharging.

When the voltage drop quantity is less than the reference value, thelithium-ion secondary battery is determined to have no short circuit,and it is appraised that no conductive foreign substance is presentinside the battery. On the other hand, when the voltage drop quantity isequal to or greater than the reference value, the lithium-ion secondarybattery is determined to have a short circuit, and it is appraised thata conductive foreign substance is present inside the battery.

The reference value can be experimentally obtained in advance using abattery having the same specification as the battery to be manufactured.For example, the reference value can be obtained as follows. First, alithium-ion secondary battery which has been verified in advance forhaving no conductive foreign substance incorporated and has not beensubjected to initial charging is prepared. Next, as described above, theprocedure proceeds to a step before the short circuit detecting step(A3).

Subsequently, the voltage before the self-discharging is measured, andthen, resistors having predetermined electric resistance are connectedto positive electrode and negative electrode terminals. Thepredetermined electric resistance can be determined based on the size orthe electric conduction rate of the conductive foreign substanceintended to detect. In a case where the conductive foreign substanceintended to detect is small and has low conductivity, it is preferableto use resistors having significant electric resistance.

Subsequently, self-discharging is carried out, and a value of thevoltage after the self-discharging is obtained. The difference betweenthe voltage before the self-discharging and the voltage after theself-discharging can be used as a reference value for a battery havingthe specification described above.

In a case where the short circuit detecting step (A3) is performed afterthe aging step (A2), it is preferable that the lithium-ion secondarybattery is subjected to discharging after the aging step (A2), and thevoltage of the lithium-ion secondary battery in the short circuitdetecting step (A3) is set to range of equal to or higher than 2.5 V andequal to or lower than 3.8 V. When the voltage of the lithium-ionsecondary battery is within the range, the voltage drop quantity due tothe self-discharging increases. Therefore, the presence or absence of ashort circuit of the lithium-ion secondary battery can be detected withhigher accuracy.

(Sorting Process (A4))

Subsequently, a lithium-ion secondary battery having no short circuitdetected is sorted out.

Accordingly, it is possible to obtain a highly reliable lithium-ionsecondary battery in which a short circuit is unlikely to occur betweenthe positive and negative electrodes.

(Process of Assembling Lithium-Ion Secondary Battery)

Subsequently, a step of assembling a lithium-ion secondary battery whichhas not been subjected to initial charging will be described.

A lithium-ion secondary battery which has not been subjected to initialcharging is not particularly limited and can be produced in accordancewith a known method. For example, the lithium-ion secondary batterythereof is manufactured in accordance with a known method by using apositive electrode, a separator, a negative electrode, and anelectrolyte.

For example, a layered body or a wound body can be used as the positiveelectrode and the negative electrode. As an exterior body, a metalexterior body or an aluminum laminate exterior body can be suitablyused. The shape of the lithium-ion secondary battery may be any shape ofa coin type, a button type, a sheet type, a cylinder type, a squaretype, a flat type, and the like.

For example, the positive electrode and the negative electrode of thepresent embodiment can be manufactured as follows.

First, electrode slurry is prepared.

Electrode slurry of the present embodiment can be prepared in accordancewith a generally known method. Accordingly, the preparation is notparticularly limited. For example, the electrode slurry can be preparedby mixing an active material, a binder, a thickener, and a conductiveassistant by means of a mixer and causing the mixture to dispersed ordissolved in a solvent or an aqueous medium. The mixture ratio of thematerials in the electrode slurry is suitably determined in accordancewith the purpose of use or the like of a battery.

As the mixer, a known mixer such as a ball mill and a planetary mixercan be used. Accordingly, the mixer is not particularly limited. Themixing method is not particularly limited either, and mixing can beperformed in accordance with a known method.

A generally known material can be used as the active material used inthe present embodiment. The electrode active material is suitablyselected in accordance with the purpose of use or the like of a battery.In addition, when a positive electrode is produced, a positive electrodeactive material is used, and when a negative electrode is produced, anegative electrode active material is used.

The positive electrode active material of the present embodiment is notparticularly limited as long as the material is an ordinary positiveelectrode active material which can be used for a positive electrode ofa lithium-ion secondary battery. However, for example, it is possible touse a material which can reversibly release and store lithium ion andhas high electron conductivity such that electron transport can beeasily carried out. Examples of the positive electrode active materialinclude composite oxide of lithium and transition metal, such aslithium-nickel composite oxide, lithium-cobalt composite oxide,lithium-manganese composite oxide, lithium-manganese-nickel compositeoxide, and lithium-nickel-cobalt-aluminum composite oxide; transitionmetal sulfide such as TiS₂, FeS, and MoS₂; transition metal oxide suchas MnO, V₂O₅, V₆O₁₃, and TiO₂; and olivine-type lithium phosphorusoxide.

The negative electrode active material of the present embodiment is notparticularly limited as long as the material is an ordinary negativeelectrode active material which can be used for a negative electrode ofa lithium-ion secondary battery. However, examples of the negativeelectrode active material include carbon materials such as naturalgraphite, artificial graphite, resin charcoal, carbon fiber, activatedcarbon, hard carbon, and soft carbon; lithium-based metal such aslithium metal and lithium alloy; metal such as silicon and tin;conductive polymers such as polyacene, polyacetylene, and polypyrrole.

The electrode slurry of the present embodiment may further include abinder which plays a role of binding the active materials, and an activematerial and a current collector together.

The binder of the present embodiment is not particularly limited as longas the binder is an ordinary binder which can be used for a lithium-ionsecondary battery. However, Examples of the binder include polyvinylalcohol, polyacrylic acid, carboxymethyl cellulose,polytetrafluoroethylene, polyvinylidene fluoride, styrenebutadiene-based rubber, and polyimide. These binders may be used alone,or two or more thereof may be used in a combination.

Among the binders described above, due to excellent binding properties,polyvinylidene fluoride or styrene butadiene-based rubber is preferable.

The usage form of the binder of the present embodiment is notparticularly limited. However, due to environmental friendliness andexcellent binding properties, it is preferable to use a so-calledwater-based binder which is used in a latex state where the binder isdispersed or dissolved in an aqueous medium.

From the viewpoint of ensuring fluidity suitable for coating, theelectrode slurry of the present embodiment may further a thickener. Thethickener of the present embodiment is not particularly limited as longas the thickener is an ordinary thickener which can be used for alithium-ion secondary battery. However, Examples of the thickenerinclude cellulose-based polymers such as carboxymethylcellulose,methylcellulose, and hydroxypropylcellulose, ammonium salts thereof, andalkali metal salt thereof; soluble polymers such as polycarboxylic acid,polyethylene oxide, polyvinyl pyrrolidone, polyacrylic acid salt, andpolyvinyl alcohol. These thickeners may be used alone, or two or morethereof may be used in a combination.

The electrode slurry of the present embodiment may further include aconductive assistant. The conductive assistant of the present embodimentis not particularly limited as long as the conductive assistant is anordinary conductive assistant which can be used for a lithium-ionsecondary battery. However, Examples of include carbon materials such asacetylene black, Ketjenblack, carbon black, and vapor-grown carbonfibers.

Subsequently, a current collector is coated with the obtained electrodeslurry and is dried.

A generally known method can be used as a method of coating a currentcollector with electrode slurry. Examples of the coating method caninclude a reverse roll method, a direct roll method, a doctor blademethod, a knife method, an extrusion method, a curtain method, a gravuremethod, a bar method, a dipping method, and a squeezing method.

Only one surface of the current collector may be coated with theelectrode slurry, or both surfaces may be coated. In a case where bothsurfaces of the current collector are coated, the current collector maybe coated successively one surface at a time or both surfaces may becoated at the same time. In addition, the surface of the currentcollector may be coated continuously or intermittently. The thickness,the length, and the width of a coating layer can be suitably determinedin accordance with the size of a battery.

A generally known method can be used as a method of drying coatedelectrode slurry. Particularly, it is preferable that hot air, vacuum,infrared rays, far infrared rays, electron beams, and warm air are usedalone or in a combination. An ordinary drying temperature ranges ofequal to or higher than 30° C. and equal to or lower than 350° C.

The current collector used for manufacturing the electrode of thepresent embodiment is not particularly limited as long as the currentcollector is an ordinary current collector which can be used for alithium-ion secondary battery. However, from the viewpoint of price,availability, electrochemical stability, and the like, it is preferableto use aluminum for a positive electrode and copper for a negativeelectrode. In addition, the shape of the current collector is notparticularly limited either. However, for example, it is possible to usea foil current collector having a thickness ranging from 0.001 mm to 0.5mm.

The electrode for a lithium-ion secondary battery of the presentembodiment may be subjected to pressing as necessary. A generally knownmethod can be used as a pressing method. Examples of the pressing methodinclude a die-pressing method and a calendar pressing method. Thepressure of pressing is not particularly limited. For example, thepressure ranges from 0.2 t/cm² to 3 t/cm².

Compounding of the electrode for a lithium-ion secondary battery thepresent embodiment is not particularly limited for being suitablydetermined in accordance with the purpose of use or the like of abattery. The compounding thereof can be set based on generally knowninformation.

The thickness and the density of layers of the positive electrode activematerial and the negative electrode active material of the presentembodiment is not particularly limited for being suitably determined inaccordance with the purpose of use or the like of a battery. Thethickness and the density thereof can be set based on generally knowninformation.

The lithium-ion secondary battery of the present embodiment can beobtained by layering the positive electrode and the negative electrode,which have been obtained through the above-described procedure, via theseparator in an atmosphere of dry air or inert gas, or winding thelayered positive electrode and negative electrode, and then byaccommodating the result thereof in a battery can or sealing the batterywith a flexible film or the like formed of a layered body of syntheticresin and metal foil.

For example, in the lithium-ion secondary battery of the presentembodiment, the positive electrode and the negative electrode aredisposed face to face via the separator in a state of being dipped inthe electrolytic solution.

As the shape of the lithium-ion secondary battery, it is possible toemploy various types of shape such as a square type, a paper type, alayer type, a cylinder type, and a coin type. The exterior material andother constituent members are not particularly limited and may beselected in accordance with the shape of a battery.

As the electrolyte in the electrolytic solution of the lithium-ionsecondary battery, any known lithium salt can be used. The electrolytemay be selected in accordance with the type of the active material.Examples of the electrolyte include, LiClO₄, LiBF₆, LiPF₆, LiCF₃SO₃,LiCF₃CO₂, LiAsF₆, LiSbF₆, LiB₁₀Cl₁₀, LiAlCl₄, LiCl, LiBr, LiB(C₂H₅)₄,CF₃SO₃Li, CH₃SO₃Li, LiCF₃SO₃, LiC₄F₉SO₃, Li(CF₃SO₂)₂N, and lower fattyacid lithium carboxylate.

The menstruum in which the electrolyte is dissolved is not particularlylimited as long as the menstruum is ordinarily used as liquid in whichan electrolyte is dissolved. Examples of the menstruum includecarbonates such as ethylene carbonate (EC), propylene carbonate (PC),butylene carbonate (BC), dimethyl carbonate (DMC), diethyl carbonate(DEC), methylethyl carbonate (MEC), and vinylene carbonate (VC);lactones such as γ-butyrolactone and γ-valerolactone; ethers such astrimethoxymethane, 1,2-dimethoxyethane, diethyl ether, 2-ethoxyethane,tetrahydrofuran, and 2-methyltetrahydrofuran; sulfoxides such asdimethylsulfoxide; oxolanes such as 1,3-dioxolane and4-methyl-1,3-dioxolane; nitrogen-containing compounds such asacetonitrile, nitromethane, formamide, and dimethylformamide; organicacid esters such as methyl formate, methyl acetate, ethyl acetate, butylacetate, methyl propionate, and ethyl propionate; phosphoric acidtriester or diglymes; triglymes; sulfolanes such as sulfolane andmethylsulfolane; oxazolidinones such as 3-methyl-2-oxazolidinone; andsultones such as 1,3-propane sultone, 1,4-butane sultone, andnaphthasultone. These may be used alone, or two or more thereby may beused in a combination.

Examples of the separator include a porous substrate. Examples of theform of the separator include a membrane, a film, and non-woven fabric.

Examples of the porous separator include polyolefin-based porousseparators such as a polypropylene-based porous separator and apolyethylene-based porous separator; and separators such aspolyvinylidene fluoride, polyethylene oxide, polyacrylonitrile, and apolyvinylidene fluoride hexafluoropropylene copolymer.

Second Embodiment: Method of Manufacturing Lithium-Ion Secondary Battery

Next, a method of manufacturing a lithium-ion secondary batteryaccording to a second embodiment will be described. FIG. 2 is a flowchart illustrating an example of the method of manufacturing alithium-ion secondary battery according to the second embodiment.

The method of manufacturing a lithium-ion secondary battery of thepresent embodiment includes at least four steps (B1) to (B4) as follows:

(B1) an initial charging step of charging the lithium-ion secondarybattery, which has not been subjected to initial charging, under acondition in which viscosity of an electrolytic solution is equal to orhigher than 6.0 mPa·s;

(B2) an aging step of leaving the lithium-ion secondary battery under acondition in which viscosity of an electrolytic solution is equal to orlower than 4.5 mPa·s after the initial charging step (B1);

(B3) a short circuit detecting step of detecting the presence or absenceof a short circuit of the lithium-ion secondary battery by measuring avoltage drop quantity of the lithium-ion secondary battery and comparingthe voltage drop quantity with a reference value; and

(B4) a sorting step of sorting out a lithium-ion secondary battery inwhich no short circuit is detected.

According to the method of manufacturing a lithium-ion secondary batteryof the present embodiment, when at least the four steps (B1) to (B4)described above are included, a lithium-ion secondary battery having aconductive foreign substance incorporated therein can be detected withhigh sensitivity, so that it is possible to efficiently obtain alithium-ion secondary battery in which a short circuit is unlikely tooccur between positive and negative electrodes.

Upon investigation of the inventors, it has become clear that the methoddisclosed in Patent Document 1 has low sensitivity for detecting aconductive foreign, for example, it is not possible to detect alithium-ion secondary battery, within a practical period of time, inwhich a minute amount of stainless steel having a high risk of beingincorporated during a manufacturing step is incorporated.

Thus, the inventors have intensively and repetitively investigated inorder to achieve the objects described above. As a result, it has beenfound that sensitivity for detecting a conductive foreign substanceinside a lithium-ion secondary battery is improved by adjusting theviscosity of an electrolytic solution in the lithium-ion secondarybattery in the initial charging step (B1) and the aging step (B2)respectively within particular ranges, and the present invention hasbeen completed.

That is, in the method of manufacturing a lithium-ion secondary batteryof the present embodiment, as described above, the viscosity of anelectrolytic solution in the lithium-ion secondary battery in theinitial charging step (B1) and the aging step (B2) is adjusted to theparticular ranges. It is assumed that when the viscosity of anelectrolytic solution in the lithium-ion secondary battery in theinitial charging step (B1) is within the range described above, seedcrystal of a precipitate of a conductive foreign substance can be formedin an acute-angled manner. In addition, it is assumed that when theviscosity of an electrolytic solution in the lithium-ion secondarybattery in the aging step (B2) is within the range described above, theseed crystal can grow effectively while the acute-angled form ismaintained.

For the reason described above, according to the method of manufacturinga lithium-ion secondary battery of the present embodiment, it ispossible to accurately detect and eliminate a lithium-ion secondarybattery in which a conductive foreign substance, such as stainless steelthat is difficult to be detected by a detection technology in therelated art, having a high risk of being incorporated during amanufacturing step is incorporated. That is, according to the method ofmanufacturing a lithium-ion secondary battery of the present embodiment,it is possible to remove a lithium-ion secondary battery as a defectiveunit in which a short circuit occurs between the positive and negativeelectrodes due to a precipitate of a conductive foreign substance sothat deterioration of battery performance is likely to occur in a laterstage in a case where a force is applied such that the positiveelectrode and the negative electrode approach each other when in actualuse or in a case of being used for a long period of time even though nodefect has occurred at the time of inspection. Therefore, it is possibleto efficiently obtain a highly reliable lithium-ion secondary battery inwhich a short circuit is unlikely to occur between the positive andnegative electrodes.

Hereinafter, each of the steps will be described.

(Initial Charging Process (B1))

First, a lithium-ion secondary battery which has not been subjected toinitial charging is charged under a condition in which viscosity of anelectrolytic solution is equal to or higher than 6.0 mPa·s.

The initial charging step (B1) is a step in which a lithium-ionsecondary battery in a state where assembling is completed (anelectrolytic solution is injected, and the battery is sealed) is chargedfor the first time to a predetermined capacity. It is preferable thatcharging in the initial charging step (B1) is carried out by constantcurrent/constant voltage charging (CCCV charging).

The viscosity of an electrolytic solution in the lithium-ion secondarybattery in the initial charging step (B1) is equal to or higher than 6.0mPa·s. However, from the viewpoint of being able to further improvesensitivity for detecting a conductive foreign substance, the viscosityis more preferably equal to or higher than 7.0 mPa·s.

It is assumed that when the viscosity of an electrolytic solution isequal to or higher than the lower limit value, diffusion of ion of aconductive foreign substance in the electrolytic solution is suppressed,and seed crystal of a precipitate of a conductive foreign substance canbe formed in an acuter-angled manner, so that sensitivity for detectinga conductive foreign substance can be improved.

For example, the upper limit value for the viscosity of an electrolyticsolution in the lithium-ion secondary battery in the initial chargingstep (B1) is equal to or lower than 15 mPa·s.

Here, the viscosity of an electrolytic solution in the lithium-ionsecondary battery can be adjusted by adjusting the ambient temperaturein the initial charging step (B1) or adjusting the type or concentrationof an electrolyte, the type of a menstruum in which the electrolyte isdissolved, and the like.

(Aging Process (B2))

Subsequently, the lithium-ion secondary battery is left under acondition in which viscosity of an electrolytic solution is equal to orlower than 4.5 mPa·s after the initial charging step (B1).

The viscosity of an electrolytic solution in the lithium-ion secondarybattery in the aging step (B2) is equal to or lower than 4.5 mPa·s.However, from the viewpoint of being able to detect a conductive foreignsubstance inside a lithium-ion secondary battery within a shorter periodof time, the viscosity is preferably equal to or lower than 4.0 mPa·sand is particularly preferably equal to or lower than 3.5 mPa·s.

It is assumed that when the viscosity of an electrolytic solution isequal to or lower than the upper limit value, diffusion of ion of aconductive foreign substance in the electrolytic solution becomesfavorable, and the seed crystal of a conductive foreign substance cangrow faster. Therefore, a conductive foreign substance inside alithium-ion secondary battery can be detected within a shorter period oftime.

For example, the lower limit value for the viscosity of an electrolyticsolution in the lithium-ion secondary battery in the aging step (B2) isequal to or higher than 1.5 mPa·s.

Here, the viscosity of an electrolytic solution can be adjusted byadjusting the ambient temperature in the aging step (B2) or adjustingthe type or concentration of an electrolyte, the type of a menstruum inwhich the electrolyte is dissolved, and the like.

In addition, it is preferable that the aging step (B2) is performedwithout carrying out charging and discharging even once after theinitial charging step (B1). In this manner, a conductive foreignsubstance can be detected within a shorter period of time.

In addition, the voltage of a lithium-ion secondary battery when theaging step (B2) starts is preferably equal to or higher than 3.80 V, ismore preferably equal to or higher than 3.90 V, and is particularlypreferably equal to or higher than 4.00 V. When the voltage of alithium-ion secondary battery when the aging step (B2) starts is equalto or higher than the lower limit value, a conductive foreign substancecan be detected with higher sensitivity within a shorter period of time.

In addition, the voltage of a lithium-ion secondary battery when theaging step (B2) starts is preferably equal to or lower than 4.40 V, ismore preferably equal to or lower than 4.30 V, and is particularlypreferably equal to or lower than 4.20 V. When the voltage of alithium-ion secondary battery when the aging step (B2) starts is equalto or lower than the upper limit value, it is possible to furthersuppress deterioration of the cell characteristics (particularly,charging and discharging capacity) of a lithium-ion secondary battery inthe aging step (B2).

In addition, in the aging step (B2), the lithium-ion secondary batteryis preferably left for equal to or longer than two days, is morepreferably left for equal to or longer than four days, and isparticularly preferably left for equal to or longer than five days. Inthe aging step (B2), when the lithium-ion secondary battery is left forequal to or higher than the lower limit value, a conductive foreignsubstance can be detected with higher sensitivity.

In addition, in the aging step (B2), the lithium-ion secondary batteryis preferably left for equal to or shorter than ten days leave and ismore preferably left for equal to or shorter than eight days. Accordingto the method of manufacturing a lithium-ion secondary battery of thepresent embodiment, a conductive foreign substance inside a lithium-ionsecondary battery can be sensitively detected. Therefore, even thoughthe period of time for being left in the aging step (B2) is equal to orlower than the upper limit value, a lithium-ion secondary battery havinga conductive foreign substance incorporated therein can be accuratelydetected and eliminated, so that it is possible to efficiently obtain alithium-ion secondary battery in which a short circuit is unlikely tooccur between positive and negative electrodes.

(Short Circuit Detecting Process (B3), Sorting Process (B4), and Processof Assembling Lithium-Ion Secondary Battery)

The short circuit detecting step (B3), the sorting step (B4), and thestep of assembling a lithium-ion secondary battery can be respectivelyperformed in accordance with the short circuit detecting step (A3), thesorting step (A4), and the step of assembling a lithium-ion secondarybattery in the method of manufacturing a lithium-ion secondary batteryaccording to the first embodiment. The detailed description will not berepeated herein.

Third Embodiment: Method of Evaluating Lithium-Ion Secondary Battery

Next, a method of evaluating a lithium-ion secondary battery accordingto a third embodiment will be described. FIG. 3 is a flow chartillustrating an example of the method of evaluating a lithium-ionsecondary battery according to the third embodiment.

The method of evaluating a lithium-ion secondary battery of the presentembodiment includes at least three steps (C1) to (C3) as follows:

(C1) a charging step of charging the lithium-ion secondary battery undera temperature environment ranging of equal to or higher than −20° C. andequal to or lower than 15° C.;

(C2) an aging step of leaving the lithium-ion secondary battery under atemperature environment ranging of equal to or higher than 30° C. andequal to or lower than 80° C. after the charging step (C1); and

(C3) a short circuit detecting step of detecting the presence or absenceof a short circuit of the lithium-ion secondary battery by measuring avoltage drop quantity of the lithium-ion secondary battery and comparingthe voltage drop quantity with a reference value.

According to the method of evaluating a lithium-ion secondary battery ofthe present embodiment, when at least the three steps (C1) to (C3)described above are included, it is possible to accurately detect alithium-ion secondary battery in which a short circuit is likely tooccur between positive and negative electrodes.

Upon investigation of the inventors, it has become clear that the methoddisclosed in Patent Document 1 has low sensitivity for detecting aconductive foreign, for example, it is not possible to detect alithium-ion secondary battery, within a practical period of time, inwhich a minute amount of stainless steel having a high risk of beingincorporated during a manufacturing step is incorporated.

Thus, the inventors have intensively and repetitively investigated inorder to achieve the objects described above. As a result, it has beenfound that sensitivity for detecting a conductive foreign substanceinside a lithium-ion secondary battery is improved by respectivelyperforming the charging step (C1) and the aging step (C2) withinparticular temperature ranges, and the present invention has beencompleted.

That is, in method of evaluating a lithium-ion secondary battery of thepresent embodiment, as described above, the ambient temperature in thecharging step (C1) and the aging step (C2) are respectively adjusted toparticular ranges. It is assumed that when the ambient temperature inthe charging step (C1) is within the range described above, seed crystalof a precipitate of a conductive foreign substance can be formed in anacute-angled manner. In addition, it is assumed that when the ambienttemperature in the aging step (C2) is within the range described above,the seed crystal can grow effectively while the acute-angled form ismaintained.

For the reason described above, according to the method of evaluating alithium-ion secondary battery of the present embodiment, it is possibleto efficiently detect a lithium-ion secondary battery in which aconductive foreign substance, such as stainless steel that is difficultto be detected by a detection technology in the related art, having ahigh risk of being incorporated during a manufacturing step isincorporated. That is, according to the method of evaluating alithium-ion secondary battery of the present embodiment, it is possibleto detect a lithium-ion secondary battery in which a short circuitoccurs between the positive and negative electrodes due to a precipitateof a conductive foreign substance so that deterioration of batteryperformance is likely to occur in a later stage in a case where a forceis applied such that the positive electrode and the negative electrodeapproach each other when in actual use or in a case of being used for along period of time.

Hereinafter, each of the steps will be described.

(Charging Process (C1))

First, a lithium-ion secondary battery is charged under a temperatureenvironment ranging of equal to or higher than −20° C. and equal to orlower than 15° C.

The charging step (C1) is a step in which a lithium-ion secondarybattery is charged to a predetermined capacity. It is preferable thatcharging in the charging step (C1) is carried out by constantcurrent/constant voltage charging (CCCV charging).

The ambient temperature in the charging step (C1) ranges of equal to orhigher than −20° C. and equal to or lower than 15° C. However, theambient temperature preferably ranges of equal to or higher than −10° C.and equal to or lower than 10° C. and more preferably ranges of equal toor higher than −8° C. and equal to or lower than 8° C. When thetemperature in the charging step (C1) is equal to or lower than theupper limit value, it is assumed that seed crystal of a precipitate of aconductive foreign substance can be formed in an acuter-angled manner.In addition, when the temperature in the charging step (C1) is equal toor higher than the lower limit value, deterioration of the cellcharacteristics (particularly, charging and discharging capacity) of alithium-ion secondary battery in the charging step (C1) can be furthersuppressed.

In addition, from the viewpoint of being able to improve sensitivity fordetecting a conductive foreign substance, the viscosity of anelectrolytic solution in the lithium-ion secondary battery in thecharging step (C1) is preferably equal to or higher than 6.0 mPa·s andis more preferably equal to or higher than 7.0 mPa·s.

It is assumed that when the viscosity of an electrolytic solution isequal to or higher than the lower limit value, diffusion of ion of aconductive foreign substance in the electrolytic solution is suppressed,and seed crystal of a precipitate of a conductive foreign substance canbe formed in an acuter-angled manner, so that sensitivity for detectinga conductive foreign substance can be improved.

The upper limit value for the viscosity of an electrolytic solution inthe lithium-ion secondary battery in the charging step (C1) is equal toor lower than 15 mPa·s.

Here, the viscosity of an electrolytic solution in the lithium-ionsecondary battery can be adjusted by adjusting the ambient temperaturein the charging step (C1) or adjusting the type or concentration of anelectrolyte, the type of a menstruum in which the electrolyte isdissolved, and the like.

(Aging Process (C2) and Short Circuit Detecting Process (C3))

The aging step (C2) and the short circuit detecting step (C3) can berespectively performed in accordance with the aging step (A2) and theshort circuit detecting step (A3) in the method of manufacturing alithium-ion secondary battery according to the first embodiment. Thedetailed description will not be repeated herein.

Fourth Embodiment: Method of Evaluating Lithium-Ion Secondary Battery

Next, a method of evaluating a lithium-ion secondary battery accordingto a fourth embodiment will be described. FIG. 4 is a flow chartillustrating an example of the method of evaluating a lithium-ionsecondary battery according to the fourth embodiment.

The method of evaluating a lithium-ion secondary battery of the presentembodiment includes at least three steps (D1) to (D3) as follows:

(D1) a charging step of charging the lithium-ion secondary battery undera condition in which viscosity of an electrolytic solution is equal toor higher than 6.0 mPa·s;

(D2) an aging step of leaving the lithium-ion secondary battery under acondition in which viscosity of an electrolytic solution is equal to orlower than 4.5 mPa·s after the charging step (D1); and

(D3) a short circuit detecting step of detecting the presence or absenceof a short circuit of the lithium-ion secondary battery by measuring avoltage drop quantity of the lithium-ion secondary battery and comparingthe voltage drop quantity with a reference value.

According to the method of evaluating a lithium-ion secondary battery ofthe present embodiment, when at least the three steps (D1) to (D3)described above are included, it is possible to accurately detect alithium-ion secondary battery in which a short circuit is likely tooccur between positive and negative electrodes.

Upon investigation of the inventors, it has become clear that the methoddisclosed in Patent Document 1 has low sensitivity for detecting aconductive foreign, for example, it is not possible to detect alithium-ion secondary battery, within a practical period of time, inwhich a minute amount of stainless steel having a high risk of beingincorporated during a manufacturing step is incorporated.

Thus, the inventors have intensively and repetitively investigated inorder to achieve the objects described above. As a result, it has beenfound that sensitivity for detecting a conductive foreign substanceinside a lithium-ion secondary battery is improved by adjusting theviscosity of an electrolytic solution in the lithium-ion secondarybattery in the charging step (D1) and the aging step (D2) respectivelywithin particular ranges, and the present invention has been completed.

That is, in method of evaluating a lithium-ion secondary battery of thepresent embodiment, as described above, the viscosity of an electrolyticsolution in the lithium-ion secondary battery in the charging step (D1)and the aging step (D2) is adjusted to the particular ranges. It isassumed that when the viscosity of an electrolytic solution in thelithium-ion secondary battery in the charging step (D1) is within therange described above, seed crystal of a precipitate of a conductiveforeign substance can be formed in an acute-angled manner. In addition,it is assumed that when the viscosity of an electrolytic solution in thelithium-ion secondary battery in the aging step (D2) is within the rangedescribed above, the seed crystal can grow effectively while theacute-angled form is maintained.

For the reason described above, according to the method of evaluating alithium-ion secondary battery of the present embodiment, it is possibleto accurately detect a lithium-ion secondary battery in which aconductive foreign substance, such as stainless steel that is difficultto be detected by a detection technology in the related art, having ahigh risk of being incorporated during a manufacturing step isincorporated. That is, according to the method of evaluating alithium-ion secondary battery of the present embodiment, it is possibleto detect a lithium-ion secondary battery in which a short circuitoccurs between the positive and negative electrodes due to a precipitateof a conductive foreign substance so that deterioration of batteryperformance is likely to occur in a later stage in a case where a forceis applied such that the positive electrode and the negative electrodeapproach each other when in actual use or in a case of being used for along period of time.

Hereinafter, each of the steps will be described.

(Charging Process (D1))

First, a lithium-ion secondary battery is charged under a condition inwhich viscosity of an electrolytic solution is equal to or higher than6.0 mPa·s.

The charging step (D1) is a step in which a lithium-ion secondarybattery is charged to a predetermined capacity. It is preferable thatcharging in the charging step (D1) is carried out by constantcurrent/constant voltage charging (CCCV charging).

The viscosity of an electrolytic solution in the lithium-ion secondarybattery in the charging step (D1) is equal to or higher than 6.0 mPa·s.However, from the viewpoint of being able to further improve sensitivityfor detecting a conductive foreign substance, the viscosity is morepreferably equal to or higher than 7.0 mPa·s.

It is assumed that when the viscosity of an electrolytic solution isequal to or higher than the lower limit value, diffusion of ion of aconductive foreign substance in the electrolytic solution is suppressed,and seed crystal of a precipitate of a conductive foreign substance canbe formed in an acuter-angled manner, so that sensitivity for detectinga conductive foreign substance can be improved.

For example, the upper limit value for the viscosity of an electrolyticsolution in the lithium-ion secondary battery in the charging step (D1)is equal to or lower than 15 mPa·s.

Here, the viscosity of an electrolytic solution in the lithium-ionsecondary battery can be adjusted by adjusting the ambient temperaturein the charging step (D1) or adjusting the type or concentration of anelectrolyte, the type of a menstruum in which the electrolyte isdissolved, and the like.

(Aging Process (D2))

The aging step (D2) can be performed in accordance with the aging step(B2) in the method of manufacturing a lithium-ion secondary batteryaccording to the second embodiment. The detailed description will not berepeated herein.

(Short Circuit Detecting Process (D3))

The short circuit detecting step (D3) can be performed in accordancewith the short circuit detecting step (A3) in the method ofmanufacturing a lithium-ion secondary battery according to the firstembodiment. The detailed description will not be repeated herein.

The present invention is not limited to the embodiments, and changes,improvements, and the like are included in the present invention withinthe scope in which the objects of the present invention can be achieved.

EXEMPLARY EMBODIMENT

Hereinafter, the present invention will be described through ExemplaryEmbodiments and Comparative Examples. However, the present invention isnot limited thereto.

Exemplary Embodiment 1

1. Assembling of Lithium-Ion Secondary Battery

(Production of Positive Electrode)

Composite oxide having LiMn₂O₄ and LiNi_(0.8)Co_(0.1)Al_(0.1)O₂ as maincomponents was used as a positive electrode active material. Carbonblack was used as a conductive assistant. Polyvinylidene fluoride (PVdF)was used as a binder. Those were dispersed in N-methyl-2-pyrrolidone,and slurry was prepared. Aluminum foil which served as a positiveelectrode current collector and had a thickness of 20 μm wascontinuously coated with this slurry and was dried. Then, a positiveelectrode roll provided with the positive electrode current collectorhaving a coated portion and an uncoated portion, which was not coated,was produced.

This positive electrode roll was punched leaving the uncoated portionwhich would serve as a tab to be connected to a positive electrodeterminal, such that the dimensions excluding a positive electrode tabbecame the height of 125 mm and the width of 65 mm, and then a positiveelectrode was obtained.

Subsequently, a stainless steel ball (diameter of 200 μm) was pressedinto the coated portion of a part of the positive electrode using aglass plate.

(Production of Negative Electrode)

Artificial graphite (average particle size d₅₀: 20 μm) was used as anegative electrode active material. Carboxymethyl cellulose was used asa thickener. Styrene butadiene-based rubber was used as a binder.Acetylene black was used as a conductive assistant. Those were dispersedin water, and slurry was prepared. Copper foil which served as anegative electrode current collector and had a thickness of 10 μm wascontinuously coated with this slurry and was dried. Then, a negativeelectrode roll provided with the negative electrode current collectorhaving a coated portion and an uncoated portion, which was not coated,was produced.

This negative electrode roll was punched leaving the uncoated portionwhich would serve as a tab to be connected to a negative electrodeterminal, such that the dimensions excluding a negative electrode tabbecame the height of 130 mm and the width of 70 mm, and then a negativeelectrode was realized.

(Assembling of Layered-Type Laminate Battery)

One positive electrode in which the stainless steel ball was embedded,five positive electrodes in which no stainless steel ball was embedded,seven negative electrodes, and twelve separators (microporouspolyethylene films having thicknesses of 25 μm) were prepared forming aset of [negative electrode-separator-positive electrode having nostainless steel ball embedded-separator]. After four sets thereof werelayered, a set of [negative electrode-separator-positive electrodehaving a stainless steel ball embedded-separator] was layered. Lastly, aset of [negative electrode-separator-positive electrode having nostainless steel ball embedded-separator-negative electrode] was layered.The negative electrode terminal or the positive electrode terminal wasprovided therein, and a layered body with a SUS ball was obtained.Subsequently, an electrolytic solution and the obtained layered body wasaccommodated in a flexible film, so that a layered-type laminate battery(2 Ah cell), that is, a lithium-ion secondary battery was obtained.Here, the electrolytic solution was obtained by causing LiPF₆ (lithiumsalt) to be dissolved in a mixed menstruum obtained by mixing ethylenecarbonate (EC) and diethyl carbonate (DEC) by 30:70 (volume ratio), suchthat 1.0 mol/L was realized.

2. Charging/Discharging Test of Layered-Type Laminate Battery

A laminate battery which had not been subjected to initial charging wassubjected to CCCV charging under the temperature environment of 5° C.and conditions of the charge current of 0.25 ItA, the upper limitvoltage of 4.05 V, and the total charging time of 360 minutes (initialcharging step). Subsequently, the laminate battery subjected to theinitial charging was left at 50° C. for seven days without carrying outcharging and discharging even once after the initial charging step(aging step). Subsequently, the laminate battery was subjected toconstant current discharging under conditions of the lower limit voltageof 2.5 V and the discharge current of 0.3 ItA and then was charged for60 minutes under conditions of the voltage of 3.3 V and the chargecurrent of 0.3 ItA. Subsequently, the laminate battery was left at 25°C. for fourteen days for self-discharging (short circuit detectingstep). In this case, the difference between the voltage of the secondday after being left and the voltage of the fourteenth day after beingleft (voltage drop quantity) was investigated.

Here, a battery of which the voltage drop quantity was equal to or morethan 10 mV was determined to have a short circuit, and a battery ofwhich thereof was less than 10 mV was determined to have no shortcircuit.

Exemplary Embodiments 2 to 4 and Comparative Examples 1 to 6

The voltage drop quantities were investigated in a manner similar tothat in Exemplary Embodiment 1 except for the ambient temperature in theinitial charging step, the charge voltage in the initial charging step,the ambient temperature in the aging step, and the days of being left inthe aging step which were varied to the values shown in Table 1.

In Table 1, as the viscosity of an electrolytic solution, viscositymeasured by using a tuning fork viscometer (manufactured by SEKONICCORPORATION, brand name: Visco Mate VM-100) is indicated, and the valuesare measured at the ambient temperature in each of the steps.

TABLE 1 Ambient Viscosity of Charge Viscosity of temperatureelectrolytic voltage in Ambient electrolytic Days Voltage T₁ in initialsolution in initial initial temperature solution in being left dropcharging charging step charging T₂ in aging aging step T₂-T₁ in agingquantity Short step [° C.] [mPa•s] step [V] step [° C.] [mPa•s] [° C.]step [day] [mV] circuit Example 1 5 7.5 4.05 50 2.9 45 7 292 PresentExample 2 5 7.5 4.20 50 2.9 45 7 61 Present Example 3 5 7.5 4.05 55 2.750 7 421 Present Example 4 −5 9.7 4.05 40 3.5 45 7 127 PresentComparative 5 7.5 4.05 25 4.8 20 7 2 Absent Example 1 Comparative 5 7.54.05 25 4.8 20 14 2 Absent Example 2 Comparative 5 7.5 4.05 25 4.8 20 213 Absent Example 3 Comparative 5 7.5 4.20 25 4.8 20 7 2 Absent Example 4Comparative 25 4.8 4.05 50 2.9 25 7 7 Absent Example 5 Comparative 453.2 4.05 50 2.9 5 7 5 Absent Example 6

As shown in Table 1, according to the method disclosed in ExemplaryEmbodiments, a short circuit due to stainless steel could be detected.That is, it is found that it is possible to detect and eliminate, withina short period of time, a lithium-ion secondary battery in which aconductive foreign substance, such as stainless steel that is difficultto be detected by a detection technology in the related art, having ahigh risk of being incorporated during a manufacturing step isincorporated. Thus, according to the method of manufacturing alithium-ion secondary battery of the present invention, it is found thatit is possible to efficiently obtain a highly reliable lithium-ionsecondary battery in which a short circuit is unlikely to occur betweenthe positive and negative electrodes.

Meanwhile, in the methods disclosed in Comparative Examples, a shortcircuit due to stainless steel could not be detected. That is, it isfound that it is difficult to detect and eliminate, within a shortperiod of time, a lithium-ion secondary battery in which a conductiveforeign substance, such as stainless steel having a high risk of beingincorporated during a manufacturing step is incorporated.

The invention claimed is:
 1. A method of determining whether alithium-ion secondary battery is a quality product or a defective unit,the method comprising: an initial charging step of charging thelithium-ion secondary battery, which has not been subjected to aninitial charging, under a temperature environment ranging of equal to orhigher than −20° C. and equal to or lower than 15° C.; an aging step ofleaving the lithium-ion secondary battery subjected to the initialcharging step under a temperature environment ranging of equal to orhigher than 30° C. and equal to or lower than 80° C. after the initialcharging step; a short circuit detecting step of detecting for a shortcircuit in the lithium-ion secondary battery subjected to the aging stepby measuring a voltage drop quantity of the lithium-ion secondarybattery and comparing the measured voltage drop quantity with apredetermined reference value; and a determining step of determiningthat the lithium-ion secondary battery subjected to said short circuitdetecting step is the quality product when the short circuit in thelithium-ion secondary battery is not detected, and determining that thelithium-ion secondary battery subjected to said short circuit detectingstep is the defective unit when the short circuit in the lithium-ionsecondary battery is detected, and wherein a viscosity of anelectrolytic solution in the lithium-ion secondary battery in theinitial charging step is equal to or higher than 6.0 mPa·s.
 2. Themethod of determining whether a lithium-ion secondary batter is aquality product or a defective unit according to claim 1, wherein(T₂−T₁) is equal to or higher than 30° C. when an ambient temperature inthe initial charging step is set to T₁ and an ambient temperature in theaging step is set to T₂.
 3. The method of determining whether alithium-ion secondary batter is a quality product or a defective unitaccording to claim 1, wherein the aging step is performed withoutcarrying out charging and discharging even once after the initialcharging step.
 4. The method of determining whether a lithium-ionsecondary batter is a quality product or a defective unit according toclaim 1, wherein a voltage of the lithium-ion secondary battery when theaging step starts is equal to or higher than 3.80 V.
 5. The method ofdetermining whether a lithium-ion secondary batter is a quality productor a defective unit according to claim 1, wherein in the aging step, thelithium-ion secondary battery is left for equal to or longer than twodays.
 6. The method of determining whether a lithium-ion secondarybatter is a quality product or a defective unit according to claim 1,wherein the lithium-ion secondary battery is subjected to dischargingafter the aging step, and a voltage of the lithium-ion secondary batteryin the short circuit detecting step is set to range of equal to orhigher than 2.5 V and equal to or lower than 3.8 V.
 7. The method ofdetermining whether a lithium-ion secondary batter is a quality productor a defective unit according to claim 1, wherein a viscosity of anelectrolytic solution in the lithium-ion secondary battery in the agingstep is equal to or lower than 4.5 mPa·s.
 8. A method of determiningwhether a lithium-ion secondary battery is a quality product or adefective unit, the method comprising: an initial charging step ofcharging the lithium-ion secondary battery, which has not been subjectedto an initial charging, under a temperature environment ranging of equalto or higher than −20° C. and equal to or lower than 15° C.; an agingstep of leaving the lithium-ion secondary battery subjected to theinitial charging step under a temperature environment ranging of equalto or higher than 30° C. and equal to or lower than 80° C. after theinitial charging step; a short circuit detecting step of detecting for ashort circuit in the lithium-ion secondary battery subjected to theaging step by measuring a voltage drop quantity of the lithium-ionsecondary battery and comparing the measured voltage drop quantity witha predetermined reference value; and a determining step of determiningthat the lithium-ion secondary battery subjected to said short circuitdetecting step is the quality product when the short circuit in thelithium-ion secondary battery is not detected, and determining that thelithium-ion secondary battery subjected to said short circuit detectingstep is the defective unit when the short circuit in the lithium-ionsecondary battery is detected, and wherein a viscosity of anelectrolytic solution in the lithium-ion secondary battery in the agingstep is equal to or lower than 4.5 mPa·s.
 9. The method of determiningwhether a lithium-ion secondary battery is a quality product or adefective unit according to claim 8, wherein (T₂−T₁) is equal to orhigher than 30° C. when an ambient temperature in the initial chargingstep is set to T₁ and an ambient temperature in the aging step is set toT₂.
 10. The method of determining whether a lithium-ion secondarybattery is a quality product or a defective unit according to claim 8,wherein the aging step is performed without carrying out charging anddischarging even once after the initial charging step.
 11. The method ofdetermining whether a lithium-ion secondary battery is a quality productor a defective unit according to claim 8, wherein a voltage of thelithium-ion secondary battery when the aging step starts is equal to orhigher than 3.80 V.
 12. The method of determining whether a lithium-ionsecondary battery is a quality product or a defective unit according toclaim 8, wherein in the aging step, the lithium-ion secondary battery isleft for equal to or longer than two days.
 13. The method of determiningwhether a lithium-ion secondary battery is a quality product or adefective unit according to claim 8, wherein the lithium-ion secondarybattery is subjected to discharging after the aging step, and a voltageof the lithium-ion secondary battery in the short circuit detecting stepis set to range of equal to or higher than 2.5 V and equal to or lowerthan 3.8 V.
 14. The method of determining whether a lithium-ionsecondary battery is a quality product or a defective unit according toclaim 13, wherein a viscosity of an electrolytic solution in thelithium-ion secondary battery in the initial charging step is equal toor higher than 6.0 mPa·s.